Hierarchies of DNA repair in mammalian cells: biological consequences

Mammalian cells exposed to genotoxic agents exhibit heterogeneous levels of repair of certain types of DNA damage in various genomic regions. For UV-induced cyclobutane pyrimidine dimers we propose that at least three levels of repair exist: (1) slow repair of inactive (X-chromosomal) genes, (2) fast repair of active housekeeping genes, and (3) accelerated repair of the transcribed strand of active genes. These hierarchies of repair may be related to chromosomal banding patterns as obtained by Giemsa staining. The possible consequences of defective DNA repair in one or more of these levels may be manifested in different clinical features associated with UV-sensitive human syndromes. Moreover, molecular analysis of hprt mutations reveals that mutations are primarily generated by DNA damage in the poorly repaired non-transcribed strand of the gene.     

UV-induced hprt mutations in a UV-sensitive hamster cell line from complementation group 3 are biased towards the transcribed strand.

The molecular nature of 254 nm ultraviolet light (UV)-induced mutations at the hypoxanthine-guanine phosphoribosyltransferase (hprt) locus in UV24 Chinese hamster ovary (CHO) cells, which are defective in nucleotide excision repair, was determined. Sequence analysis of 19 hprt mutants showed that single base substitutions (9 mutants) and tandem base changes (7 mutants) dominated the UV mutation spectrum in this cell line. Sixty-five percent of the base substitutions were GC greater than AT transitions, whereas the rest consisted of transitions and transversions at AT base pairs. Analysis of the distribution of dipyrimidine sites over the two DNA strands, where the photoproducts causing these mutations presumably were formed, showed that 12 out of 14 mutations were located in the transcribed strand of the hprt gene. A similar strand distribution of mutagenic photoproducts as in UV24 has previously been found in two other UV-sensitive Chinese hamster cell lines (V-H1 and UV5), indicating that under defective nucleotide excision repair conditions the induction of mutations is strongly biased towards lesions in the transcribed strand of the hprt gene. A plausible explanation for this phenomenon is that during DNA replication large differences exist in the error rate with which DNA polymerase(s) bypass lesions in the templates for the leading and lagging strand, respectively.     

Decreased DNA repair efficiency by loss or disruption of p53 function preferentially affects removal of cyclobutane pyrimidine dimers from non-transcribed strand and slow repair sites in transcribed strand

The tumor suppressor protein p53 plays a central role in modulating the cellular responses to DNA damage. Several recent studies, undertaken with the whole genomic DNA or full-length gene segments, have shown that p53 is involved in nucleotide excision repair and it selectively influences the adduct removal from the non-transcribed strand in the genome. In this study, we have analyzed the damage induction at nucleotide resolution by ligase-mediated polymerase chain reaction and compared the repair of ultraviolet radiation-induced cyclobutane pyrimidine dimers within exon 8 of p53 gene in normal and Li-Fraumeni syndrome fibroblasts as well as in normal and human papillomavirus 16 E6 and E7 protein-expressing human mammary epithelial cells. The results demonstrate that (i) loss or disruption of p53 function decreases efficiency of DNA repair, by preferentially affecting the repair of non-transcribed strand and of intrinsically slow repair sites in transcribed strand; (ii) mutant p53 protein affects DNA repair, at least of non-transcribed strand, in a dominant negative manner; and (iii) pRb does not have an effect on the repair of DNA damage within transcribed or non-transcribed strand. The overall data suggest that p53 could regulate excision repair or related events through direct protein-protein interaction.